third_party/llvm-project/llvm/test/CodeGen/AArch64/global-alignment.ll - cobalt - Git at Google

 ; RUN: llc -mtriple=aarch64-linux-gnu -verify-machineinstrs -o - %s | FileCheck %s

 @var32 = global [3 x i32] zeroinitializer
 @var64 = global [3 x i64] zeroinitializer
 @var32_align64 = global [3 x i32] zeroinitializer, align 8
 @alias = alias [3 x i32], [3 x i32]* @var32_align64

 define i64 @test_align32() {
 ; CHECK-LABEL: test_align32:
   %addr = bitcast [3 x i32]* @var32 to i64*

   ; Since @var32 is only guaranteed to be aligned to 32-bits, it's invalid to
   ; emit an "LDR x0, [x0, #:lo12:var32] instruction to implement this load.
   %val = load i64, i64* %addr
 ; CHECK: adrp [[HIBITS:x[0-9]+]], var32
 ; CHECK: add x[[ADDR:[0-9]+]], [[HIBITS]], {{#?}}:lo12:var32
 ; CHECK: ldr x0, [x[[ADDR]]]

   ret i64 %val
 }

 define i64 @test_align64() {
 ; CHECK-LABEL: test_align64:
   %addr = bitcast [3 x i64]* @var64 to i64*

   ; However, var64 *is* properly aligned and emitting an adrp/add/ldr would be
   ; inefficient.
   %val = load i64, i64* %addr
 ; CHECK: adrp x[[HIBITS:[0-9]+]], var64
 ; CHECK-NOT: add x[[HIBITS]]
 ; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:var64]

   ret i64 %val
 }

 define i64 @test_var32_align64() {
 ; CHECK-LABEL: test_var32_align64:
   %addr = bitcast [3 x i32]* @var32_align64 to i64*

   ; Since @var32 is only guaranteed to be aligned to 32-bits, it's invalid to
   ; emit an "LDR x0, [x0, #:lo12:var32] instruction to implement this load.
   %val = load i64, i64* %addr
 ; CHECK: adrp x[[HIBITS:[0-9]+]], var32_align64
 ; CHECK-NOT: add x[[HIBITS]]
 ; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:var32_align64]

   ret i64 %val
 }

 define i64 @test_var32_alias() {
 ; CHECK-LABEL: test_var32_alias:
   %addr = bitcast [3 x i32]* @alias to i64*

   ; Test that we can find the alignment for aliases.
   %val = load i64, i64* %addr
 ; CHECK: adrp x[[HIBITS:[0-9]+]], alias
 ; CHECK-NOT: add x[[HIBITS]]
 ; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:alias]

   ret i64 %val
 }

 @yet_another_var = external global {i32, i32}

 define i64 @test_yet_another_var() {
 ; CHECK-LABEL: test_yet_another_var:

   ; @yet_another_var has a preferred alignment of 8, but that's not enough if
   ; we're going to be linking against other things. Its ABI alignment is only 4
   ; so we can't fold the load.
   %val = load i64, i64* bitcast({i32, i32}* @yet_another_var to i64*)
 ; CHECK: adrp [[HIBITS:x[0-9]+]], yet_another_var
 ; CHECK: add x[[ADDR:[0-9]+]], [[HIBITS]], {{#?}}:lo12:yet_another_var
 ; CHECK: ldr x0, [x[[ADDR]]]
   ret i64 %val
 }

 define i64()* @test_functions() {
 ; CHECK-LABEL: test_functions:
   ret i64()* @test_yet_another_var
 ; CHECK: adrp [[HIBITS:x[0-9]+]], test_yet_another_var
 ; CHECK: add x0, [[HIBITS]], {{#?}}:lo12:test_yet_another_var
 }
	; RUN: llc -mtriple=aarch64-linux-gnu -verify-machineinstrs -o - %s \| FileCheck %s

	@var32 = global [3 x i32] zeroinitializer
	@var64 = global [3 x i64] zeroinitializer
	@var32_align64 = global [3 x i32] zeroinitializer, align 8
	@alias = alias [3 x i32], [3 x i32]* @var32_align64

	define i64 @test_align32() {
	; CHECK-LABEL: test_align32:
	%addr = bitcast [3 x i32]* @var32 to i64*

	; Since @var32 is only guaranteed to be aligned to 32-bits, it's invalid to
	; emit an "LDR x0, [x0, #:lo12:var32] instruction to implement this load.
	%val = load i64, i64* %addr
	; CHECK: adrp [[HIBITS:x[0-9]+]], var32
	; CHECK: add x[[ADDR:[0-9]+]], [[HIBITS]], {{#?}}:lo12:var32
	; CHECK: ldr x0, [x[[ADDR]]]

	ret i64 %val
	}

	define i64 @test_align64() {
	; CHECK-LABEL: test_align64:
	%addr = bitcast [3 x i64]* @var64 to i64*

	; However, var64 is properly aligned and emitting an adrp/add/ldr would be
	; inefficient.
	%val = load i64, i64* %addr
	; CHECK: adrp x[[HIBITS:[0-9]+]], var64
	; CHECK-NOT: add x[[HIBITS]]
	; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:var64]

	ret i64 %val
	}

	define i64 @test_var32_align64() {
	; CHECK-LABEL: test_var32_align64:
	%addr = bitcast [3 x i32]* @var32_align64 to i64*

	; Since @var32 is only guaranteed to be aligned to 32-bits, it's invalid to
	; emit an "LDR x0, [x0, #:lo12:var32] instruction to implement this load.
	%val = load i64, i64* %addr
	; CHECK: adrp x[[HIBITS:[0-9]+]], var32_align64
	; CHECK-NOT: add x[[HIBITS]]
	; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:var32_align64]

	ret i64 %val
	}

	define i64 @test_var32_alias() {
	; CHECK-LABEL: test_var32_alias:
	%addr = bitcast [3 x i32]* @alias to i64*

	; Test that we can find the alignment for aliases.
	%val = load i64, i64* %addr
	; CHECK: adrp x[[HIBITS:[0-9]+]], alias
	; CHECK-NOT: add x[[HIBITS]]
	; CHECK: ldr x0, [x[[HIBITS]], {{#?}}:lo12:alias]

	ret i64 %val
	}

	@yet_another_var = external global {i32, i32}

	define i64 @test_yet_another_var() {
	; CHECK-LABEL: test_yet_another_var:

	; @yet_another_var has a preferred alignment of 8, but that's not enough if
	; we're going to be linking against other things. Its ABI alignment is only 4
	; so we can't fold the load.
	%val = load i64, i64* bitcast({i32, i32}* @yet_another_var to i64*)
	; CHECK: adrp [[HIBITS:x[0-9]+]], yet_another_var
	; CHECK: add x[[ADDR:[0-9]+]], [[HIBITS]], {{#?}}:lo12:yet_another_var
	; CHECK: ldr x0, [x[[ADDR]]]
	ret i64 %val
	}

	define i64()* @test_functions() {
	; CHECK-LABEL: test_functions:
	ret i64()* @test_yet_another_var
	; CHECK: adrp [[HIBITS:x[0-9]+]], test_yet_another_var
	; CHECK: add x0, [[HIBITS]], {{#?}}:lo12:test_yet_another_var
	}